Monolayer Vanadium‐Doped Tungsten Disulfide: A Room‐Temperature Dilute Magnetic Semiconductor

Dilute magnetic semiconductors (DMS), achieved through substitutional doping of spin‐polarized transition metals into semiconducting systems, enable experimental modulation of spin dynamics in ways that hold great promise for novel magneto–electric or magneto–optical devices, especially for two‐dime...

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Published inAdvanced science Vol. 7; no. 24; pp. 2001174 - n/a
Main Authors Zhang, Fu, Zheng, Boyang, Sebastian, Amritanand, Olson, David H., Liu, Mingzu, Fujisawa, Kazunori, Pham, Yen Thi Hai, Jimenez, Valery Ortiz, Kalappattil, Vijaysankar, Miao, Leixin, Zhang, Tianyi, Pendurthi, Rahul, Lei, Yu, Elías, Ana Laura, Wang, Yuanxi, Alem, Nasim, Hopkins, Patrick E., Das, Saptarshi, Crespi, Vincent H., Phan, Manh‐Huong, Terrones, Mauricio
Format Journal Article
LanguageEnglish
Published Germany John Wiley & Sons, Inc 01.12.2020
Wiley Blackwell (John Wiley & Sons)
John Wiley and Sons Inc
Subjects
2D ferromagnets
Atmospheric pressure
Chemical vapor deposition
Communication
Communications
dilute magnetic semiconductors
ENGINEERING
MATERIALS SCIENCE
room‐temperature ferromagnetism
Semiconductors
Spectrum analysis
Transmission electron microscopy
tungsten disulfide
vanadium doping
room‐temperature ferromagnetism
tungsten disulfide
2D ferromagnets
vanadium doping
dilute magnetic semiconductors
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Summary:Dilute magnetic semiconductors (DMS), achieved through substitutional doping of spin‐polarized transition metals into semiconducting systems, enable experimental modulation of spin dynamics in ways that hold great promise for novel magneto–electric or magneto–optical devices, especially for two‐dimensional (2D) systems such as transition metal dichalcogenides that accentuate interactions and activate valley degrees of freedom. Practical applications of 2D magnetism will likely require room‐temperature operation, air stability, and (for magnetic semiconductors) the ability to achieve optimal doping levels without dopant aggregation. Here, room‐temperature ferromagnetic order obtained in semiconducting vanadium‐doped tungsten disulfide monolayers produced by a reliable single‐step film sulfidation method across an exceptionally wide range of vanadium concentrations, up to 12 at% with minimal dopant aggregation, is described. These monolayers develop p‐type transport as a function of vanadium incorporation and rapidly reach ambipolarity. Ferromagnetism peaks at an intermediate vanadium concentration of ~2 at% and decreases for higher concentrations, which is consistent with quenching due to orbital hybridization at closer vanadium–vanadium spacings, as supported by transmission electron microscopy, magnetometry, and first‐principles calculations. Room‐temperature 2D‐DMS provide a new component to expand the functional scope of van der Waals heterostructures and bring semiconducting magnetic 2D heterostructures into the realm of practical application. Room‐temperature ferromagnetism is achieved in semiconducting vanadium‐doped tungsten disulfide monolayers. A reproducible and atmospheric pressure film sulfidation growth method yields doping concentration tunability in air‐stable samples. These monolayers develop p‐type transport as a function of vanadium incorporation and rapidly reach ambipolarity. The ferromagnetic behavior in this dilute semiconductor is modeled and understood through first‐principles calculations.
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USDOE Office of Science (SC), Basic Energy Sciences (BES). Materials Sciences & Engineering Division
USDOE
FG02-07ER46438
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202001174